Click here to close
Hello! We notice that you are using Internet Explorer, which is not supported by Xenbase and may cause the site to display incorrectly.
We suggest using a current version of Chrome,
FireFox, or Safari.
???displayArticle.abstract???
CLC-5 is a H(+)/Cl(-) exchanger that is expressed primarily in endosomes but can traffic to the plasma membrane in overexpression systems. Mutations altering the expression or function of CLC-5 lead to Dent's disease. Currents mediated by this transporter show extreme outward rectification and are inhibited by acidic extracellular pH. The mechanistic origins of both phenomena are currently not well understood. It has been proposed that rectification arises from the voltage dependence of a H(+) transport step, and that inhibition of CLC-5 currents by low extracellular pH is a result of a reduction in the driving force for exchange caused by a pH gradient. We show here that the pH dependence of CLC-5 currents arises from H(+) binding to a single site located halfway through the transmembrane electric field and driving the transport cycle in a less permissive direction, rather than a reduction in the driving force. We propose that protons bind to the extracellular gating glutamate E211 in CLC-5. It has been shown that CLC-5 becomes severely uncoupled when SCN(-) is the main charge carrier: H(+) transport is drastically reduced while the rate of anion movement is increased. We found that in these conditions, rectification and pH dependence are unaltered. This implies that H(+) translocation is not the main cause of rectification. We propose a simple transport cycle model that qualitatively accounts for these findings.
???displayArticle.pubmedLink???
20513761
???displayArticle.pmcLink???PMC2888053 ???displayArticle.link???J Gen Physiol ???displayArticle.grants???[+]
Figure 1. Inhibition of CLC-5 currents by extracellular H+’s. (A) CLC-5 currents recorded from the same oocyte at various pHex. Scale bars represent 1 µA and 10 ms. (B) Current–voltage plots for the currents shown in A. Squares, pH 9; circles, pH 7.5; triangles, pH 6.0; diamonds, pH 4.5. Solid lines hold no theoretical meaning. (C) Bar representation of the currents recorded at various voltages and pHs: black bar, I(pH 8, +70 mV); white bar, I(pH 7, +90 mV); hatched gray bar, I(pH 6, +110 mV). (D) Plot of normalized currents at +60 (filled circles) and +110 (open circles) mV as a function of pH. Solid lines are fits to Eq. 3 as described in Results, with K = 8.1 × 10−7, Imax = 1.02 and Imin = 0.27 at +60 mV, and K = 2.4 × 10−6, Imax = 0.99 and Imin = 0.33 at +110 mV. (E) Plot of the mean values of the pK obtained as in D, versus voltage. Solid line is a fit to pK(V) = pK(0) + zFV/RT, where pK(V) is the pK at voltage V, pK(0) = 6.6 is the pK extrapolated at V = 0, z = 0.51 is the fraction of the membrane potential acting on the blocking ion, and F, R, and T have their usual meanings.
Figure 2. Proton inhibition of CLC-5 currents in low extracellular Cl−. (A) Plot of normalized currents at +60 (filled circles) and +110 (open circles) mV as a function of pH. Solid lines are fits to Eq. 3 as described in Results, with K = 7.1 × 10−7, Imax = 0.98 and Imin = 0.25 at +60 mV, and K = 2.1 × 10−6, Imax = 0.97 and Imin = 0.24 at +110 mV. Dotted lines represent the fits at +110 (gray) and +60 (black) mV at 100 mM [Cl−]ex. (B) Plot of the mean values of the pK obtained as in A, versus voltage. Solid line is a fit to pK(V) = pK(0) + zFV/RT, where pK(V) is the pK at voltage V, pK(0) = 6.7 is the pK extrapolated at V = 0, z = 0.56 is the fraction of the membrane potential acting on the blocking ion, and F, R, and T have their usual meanings.
Figure 3. Inhibition of CLC-5 currents in SCN−. (A) CLC-5 currents recorded from the same oocyte in various pHex. Scale bars represent 2 µA and 10 ms. (B) Current–voltage plots for the currents shown in A. Squares, pH 9; circles, pH 7.5; triangles, pH 6.0; diamonds, pH 4.5. Solid lines hold no theoretical meaning. (C) Plot of normalized currents at +60 (filled circles) and +110 (open circles) mV as a function of pH. Solid lines are fits to Eq. 3 as described in Results, with K = 6.0 × 10−7, Imax = 1.04 and Imin = 0.25 at +60 mV, and K = 2.1 × 10−6, Imax = 1.05 and Imin = 0.31 at +110 mV. Dotted lines represent the fits at +110 (gray) and +60 (black) mV at 100 mM [Cl−]ex. (D) Plot of the mean values of the pK obtained as in C, versus voltage. Solid line is a fit to pK(V) = pK(0) + zFV/RT, where pK(V) is the pK at voltage V, pK(0) = 6.9 is the pK extrapolated at V = 0, z = 0.63 is the fraction of the membrane potential acting on the blocking ion, and F, R, and T have their usual meanings.
Figure 4. Simplified transport model for CLC-5. (A) Coupled transport in Cl−. (B) Uncoupled transport mode in SCN−. Green circles, Cl− ions; red circles, H+; yellow circles, SCN− ions. The model is described in the Discussion.
Accardi,
Secondary active transport mediated by a prokaryotic homologue of ClC Cl- channels.
2004, Pubmed
Accardi,
Secondary active transport mediated by a prokaryotic homologue of ClC Cl- channels.
2004,
Pubmed
Accardi,
Separate ion pathways in a Cl-/H+ exchanger.
2005,
Pubmed
Accardi,
Synergism between halide binding and proton transport in a CLC-type exchanger.
2006,
Pubmed
Alekov,
Channel-like slippage modes in the human anion/proton exchanger ClC-4.
2009,
Pubmed
Chen,
Different fast-gate regulation by external Cl(-) and H(+) of the muscle-type ClC chloride channels.
2001,
Pubmed
,
Xenbase
De Angeli,
The nitrate/proton antiporter AtCLCa mediates nitrate accumulation in plant vacuoles.
2006,
Pubmed
Dutzler,
X-ray structure of a ClC chloride channel at 3.0 A reveals the molecular basis of anion selectivity.
2002,
Pubmed
Dutzler,
Gating the selectivity filter in ClC chloride channels.
2003,
Pubmed
,
Xenbase
Engh,
The mechanism of fast-gate opening in ClC-0.
2007,
Pubmed
Friedrich,
Mutational analysis demonstrates that ClC-4 and ClC-5 directly mediate plasma membrane currents.
1999,
Pubmed
,
Xenbase
Gadsby,
Steady-state current-voltage relationship of the Na/K pump in guinea pig ventricular myocytes.
1989,
Pubmed
Graves,
The Cl-/H+ antiporter ClC-7 is the primary chloride permeation pathway in lysosomes.
2008,
Pubmed
Hara-Chikuma,
Impaired acidification in early endosomes of ClC-5 deficient proximal tubule.
2005,
Pubmed
Hebeisen,
Anion permeation in human ClC-4 channels.
2003,
Pubmed
Jayaram,
Ion permeation through a Cl--selective channel designed from a CLC Cl-/H+ exchanger.
2008,
Pubmed
Jentsch,
CLC chloride channels and transporters: from genes to protein structure, pathology and physiology.
2008,
Pubmed
Kuang,
Proton pathways and H+/Cl- stoichiometry in bacterial chloride transporters.
2007,
Pubmed
Lobet,
Ion-binding properties of the ClC chloride selectivity filter.
2006,
Pubmed
Miller,
A provisional transport mechanism for a chloride channel-type Cl-/H+ exchanger.
2009,
Pubmed
Nakao,
[Na] and [K] dependence of the Na/K pump current-voltage relationship in guinea pig ventricular myocytes.
1989,
Pubmed
Nguitragool,
Uncoupling of a CLC Cl-/H+ exchange transporter by polyatomic anions.
2006,
Pubmed
Niemeyer,
Voltage-dependent and -independent titration of specific residues accounts for complex gating of a ClC chloride channel by extracellular protons.
2009,
Pubmed
Picollo,
Chloride/proton antiporter activity of mammalian CLC proteins ClC-4 and ClC-5.
2005,
Pubmed
Piwon,
ClC-5 Cl- -channel disruption impairs endocytosis in a mouse model for Dent's disease.
2000,
Pubmed
Scheel,
Voltage-dependent electrogenic chloride/proton exchange by endosomal CLC proteins.
2005,
Pubmed
,
Xenbase
Steinmeyer,
Cloning and functional expression of rat CLC-5, a chloride channel related to kidney disease.
1995,
Pubmed
,
Xenbase
Wang,
Proton transport pathway in the ClC Cl-/H+ antiporter.
2009,
Pubmed
Woodhull,
Ionic blockage of sodium channels in nerve.
1973,
Pubmed
Zdebik,
Determinants of anion-proton coupling in mammalian endosomal CLC proteins.
2008,
Pubmed
Zifarelli,
Intracellular proton regulation of ClC-0.
2008,
Pubmed
,
Xenbase
Zifarelli,
Conversion of the 2 Cl(-)/1 H+ antiporter ClC-5 in a NO3(-)/H+ antiporter by a single point mutation.
2009,
Pubmed
,
Xenbase
